Non-polar photosensitizer formulations for photodynamic therapy

ABSTRACT

A pharmaceutical liposomal formulation for photodynamic therapy comprising a non-polar porphyrin photosensitizer and one or more phospholipids, which are stable in storage without requiring freeze-drying is described. The liposomal formulation provides therapeutically effective amounts of the photosensitizer for intravenous administration. The phospholipids may be modified by pegylation, i.e. they contain poly ethylene glycol as an integral part of the phospholipids. The formed liposomes contain the non-polar photosensitizer within the membrane and are useful for the combined targeting of a non-polar photosensitizer and a second polar substance. When a formulation includes the presence of monosaccharides or polyalcohols, it can be efficiently freeze-dried preserving the size of the liposomal vehicles and the content of a therapeutically effective amount of the photosensitizing agent. The invention also relates to the liposome composition formed upon reconstitution with an aqueous vehicle. The freeze-dried formulation upon reconstitution with a suitable aqueous vehicle forms liposomes that are also useful for intravenous administration.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention concerns the preparation of liposomal formulations containing Temoporfin or other non-polar photosensitizers and their use in therapy, particularly using intravenous injection.

2. Information Disclosure Statement

Liposomes are artificial vesicles composed of concentric lipid bilayers separated by water-compartments and have been extensively investigated as drug delivery vehicles. Due to their structure, chemical composition and colloidal size, all of which can be well controlled by preparation methods, liposomes exhibit several properties which may be useful in various applications. The most important properties are colloidal size, i.e. rather uniform particle size distributions in the range from 20 nm to 10 μm, and special membrane and surface characteristics.

Liposomes are used as carriers for drugs and antigens because they can serve several different purposes (Storm & Crommelin, Pharmaceutical Science & Technology Today, 1, 19-31 1998). Liposome encapsulated drugs are inaccessible to metabolizing enzymes. Conversely, body components (such as erythrocytes or tissues at the injection site) are not directly exposed to the full dose of the drug. The Duration of drug action can be prolonged by liposomes because of a slower release of the drug in the body. Liposomes possessing a direction potential, that means, targeting options change the distribution of the drug over the body. Cells use endocytosis or phagocytosis mechanism to take up liposomes into the cytosol. Furthermore liposomes can protect a drug against degradation (e.g. metabolic degradation). Although sometimes successful, liposomes have limitations. Liposomes not only deliver drugs to diseased tissue, but also rapidly enter the liver, spleen, kidneys and Reticuloendothelial Systems, and leak drugs while in circulation (Harris & Chess, Nature, March 2003, 2, 214-221).

Pegylation is an alternative method to overcome these deficiencies. First, pegylation maintains drug levels within the therapeutic window for longer time periods and provides the drug as a long-circulating moiety that gradually degrades into smaller, more active, and/or easier to clear fragments. Second, it enables long-circulating drug-containing micro particulates or large macromolecules to slowly accumulate in pathological sites with affected vasculature or receptor expression and improves or enhances drug delivery in those areas. Third, it can help to achieve a better targeting effect for those targeted drugs and drug carriers which are supposed to reach pathological areas with diminished blood flow or with a low concentration of a target antigen. The benefits of pegylation typically result in an increased stability (temperature, pH, solvent, etc.), a significantly reduced immunogenicity and antigenicity, a resistance to proteases, a maintenance of catalytic activity, and improvements in solubility, among other features, and an increased liquid stability of the product and reduced agitation-induced aggregation.

Liposome membranes containing bilayers-compatible species such as poly (ethylene glycol)-linked lipids (PEG-lipid) or gangliosides are being used to prepare stealth liposomes (Papahadjopoulos et al., PNAS, 88, 11460-4 1991). Stealth liposomes have a relatively long half-life in blood circulation and show an altered biodistribution in vivo. Vaage et al. (Int. J. of Cancer 51, 942-8, 1992) prepared stealth liposomes of doxorubicin and used them to treat recently implanted and well established growing primary mouse carcinomas, and to inhibit the development of spontaneous metastases from intra-mammary tumor implants. They concluded that long circulation time of the stealth liposomes of doxorubicin formulation accounts for its superior therapeutic effectiveness. The presence of MPEG-derivatized (pegylated) lipids in the bilayers membrane of sterically stabilized liposomes effectively furnishes a steric barrier against interactions with plasma proteins and cell surface receptors that are responsible for the rapid intravascular destabilization/rupture and RES clearance seen after i.v. administration of conventional liposomes. As a result, pegylated liposomes have a prolonged circulation half-life, and the pharmacokinetics of any encapsulated agent are altered to conform to those of the liposomal carrier rather than those of the entrapped drug (Stewart et al., J. Clin. Oncol. 16, 683-691, 1998). Because the mechanism of tumor localization of pegylated liposomes is by means of extravasation through leaky blood vessels in the tumor (Northfelt et al., J. Clin. Oncol. 16, 2445-2451, 1998; Muggia et al., J. Clin. Oncol. 15, 987-993, 1997), prolonged circulation is likely to favor accumulation in the tumor by increasing the total number of passes made by the pegylated liposomes through the tumor vasculature.

Photodynamic therapy (PDT) is one of the most promising new techniques being explored for use in a variety of medical applications and is known as a well-recognized treatment for the destruction of tumors (“Pharmaceutical development and medical applications of porphyrin-type macrocycles”, T. D. Mody, J. Porphyrins Phthalocyanines, 4, 362-367 2000). Another important application of PDT is the treatment of infectious diseases due to pathogenic micro organisms including dermal, dental, suppurative, respiratory, gastro enteric, genital and other infections.

A constant problem in the treatment of infectious disease is the lack of specificity of the agents used for the treatment of disease, which results in the patient gaining a new set of maladies from the therapy.

The use of PDT for the treatment of various types of disease is limited due to the inherent features of photosensitizers. These include their high cost, extended retention in the host organism, substantial skin photo toxicity, background toxicity, low solubility in physiological solutions (which reduces its usefulness for intravascular administration as it can provoke thromboembolic accidents), and low targeting effectiveness. These disadvantages lead to the administration of extremely high doses of a photosensitizer, which dramatically increase the possibility of accumulation of the photosensitizer in non-damaged tissues and the accompanying risk of affecting non-damaged sites.

One of the prospective approaches to increase the specificity of photosensitizers and the effectiveness of PDT is a conjugation of a photosensitizer with a ligand-vector, which specifically binds to receptors on the surface of a target cell. A number of natural and synthetic molecules recognized by target cells can be used as such vectors. This approach is now used in the design of new generations of photosensitizers for the treatment of tumors (“Porphyrin-based photosensitizers for use in photodynamic therapy” E. D. Sternberg, D. Dolphin, C. Brueckner, Tetrahedron, 54, 4151-4202 1998).

Another approach to increase tumor selectivity by targeting photosensitizers to tumor cells is using liposomes, e.g. transferrin-conjugated liposomes (Derycke & De Witte, Int. J. Oncology 20, 181-187, 2002). Because non-conjugated liposomes are often easily recognized and eliminated by the reticuloendothelial system, PEG-ylated liposomes were used (Woodle & Lasic, Sterically stabilized liposomes, Biochim Biophys Acta 1113, 171-199, 1992; Dass et al., Enhanced anticancer therapy mediated by specialized liposomes. J Pharm Pharmacol 49, 972-975, 1997).

Since the application of photodynamic therapy in the treatment of cancer and other diseases is increasing rapidly, there is also a bigger demand for new photosensitizer formulations. These new photosensitizer formulations need to be more stable, easy to manufacture and to handle. Furthermore, especially more hydrophobic non-polar photosensitizers, should be able to target tissue in an efficient and selective manner.

OBJECTIVES AND BRIEF SUMMARY OF THE INVENTION

It is an object of the present invention to provide an improved photosensitizer formulation for use in photodynamic therapy (PDT).

It is another object of the present invention to incorporate non-polar photosensitizers into a liposomal membrane thus allowing non-polar and polar substances to be transported using the same vehicle.

It is a further object of the present invention to preserve the structure and size of liposomal constructs with incorporated non-polar photosensitizer during freeze-drying processes by adding monosaccharides or polyalcohols as cryoprotectants.

It is yet another object of the present invention to provide a photosensitizer formulation with improved pharmacokinetic properties.

It is still another object of the present invention to improve the transport of non-polar photosensitizers through the cell membrane and thus increasing the efficacy of PDT.

The present invention involves a pharmaceutical liposomal formulation for photodynamic therapy comprising a non-polar porphyrin photosensitizer and one or more phospholipids, which are stable in storage without requiring freeze-drying. The liposomal formulation provides therapeutically effective amounts of the photosensitizer for intravenous administration. The phospholipids may be modified by pegylation, i.e. they contain poly ethylene glycol as an integral part of the phospholipids. The formed liposomes contain the non-polar photosensitizer within the membrane and are useful for the combined targeting of a non-polar photosensitizer and a second polar substance. When a formulation includes the presence of monosaccharides or polyalcohols, it can be efficiently freeze-dried preserving the size of the liposomal vehicles and the content of a therapeutically effective amount of the photosensitizing agent. The invention also relates to the liposome composition formed upon reconstitution with an aqueous vehicle. The freeze-dried formulation upon reconstitution with a suitable aqueous vehicle forms liposomes that are also useful for intravenous administration.

The above, and other objects, features and advantages of the present invention will become apparent from the following description read in conjunction with the accompanying figures.

BRIEF DESCRIPTION OF FIGURES

FIG. 1 is a gel filtration curve of liposomal formulated mTHPC. Both, lipid components and mTHPC show the same distribution over all fractions collected.

FIG. 2 displays the light-induced fluorescence (LIF) measurement of Colo 26 tumors with intact skin, Swiss nu/nu mice 0.5 mg/kg, with intravenous injection of mTHPC, product A and B giving the accumulation in tumor as a function of time post-injection.

FIG. 3 shows the PDT-effect 6 h after intravenous injection of product A, B and mTHPC. Mice were injected intraperitoneally (i.p.). (0.25 ml) with Evans blue (1%) immediately after PDT treatment and sacrificed after 24 h.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

A pharmaceutical liposomal formulation for photodynamic therapy comprising a non-polar porphyrin photosensitizer and one or more phospholipids, which are stable in storage without requiring freeze-drying is described below. The liposomal formulation provides therapeutically effective amounts of the photosensitizer for intravenous administration. The phospholipids may be modified by pegylation, i.e. they contain poly ethylene glycol as an integral part of the phospholipids. The formed liposomes contain the non-polar photosensitizer within the membrane and are useful for the combined targeting of a non-polar photosensitizer and a second polar substance.

The formulation may be preserved by a freeze-drying procedure using a monosaccharide or polyalcohol, but need not be to have a reasonably stable shelf life. The process cycle preserves the size of the liposomal vehicle as well as the membrane content of the photosensitizing compound.

The non-polar photosensitizers in this invention include the known porphyrin based compounds. In particular photosensitizers, that are advantageously employed in the practice of this invention, are based upon porphyrin macrocycle photosensitizers, which include deuteroporphyrin, etioporphyrin, protoporphyrin, hematoporphyrin, pheophorbide and derivatives thereof, especially di- and tetra-hydroporphyrins, that have light absorption maxima in the range of 640-780 nanometers.

The phospholipids may or may not be modified by pegylation (containing poly ethylene glycol as integral part). The formed liposomes contain the non-polar photosensitizer within the membrane and are useful for the combined targeting of a non-polar photosensitizer and a second polar substance.

The photosensitizing formulations are useful to target the non-polar photosensitizer molecule to the unwanted cells or tissues or other undesirable materials and, after irradiation with an appropriated light source, to damage the target. The photosensitizing formulations are also useful to monitor unwanted cells or tissues or other undesirable materials by using fluorescence imaging methods without or with limited photochemical activation of the photosensitizer.

Especially the liposomal formulation of the invention is useful to transport non-polar photosensitizers. Non-polar substances are integrated within the membrane of the vehicles, thereby creating a structure that opens up easier, freeing the photosensitizer for action directly to the cell membrane. This mechanism delivers the photosensitizer directly to the cellular membrane system, one preferred place of action. Thus the photosensitizer, being effectively activated by illumination with an appropriate external light source, can irreversibly damage unwanted cells, tissues or other structures.

Conventionally constructed liposomal formulations are used to transport several compounds trapped into the luminal part of the vehicle. The invention focuses on the combination of two different transport compartments within one liposome allowing a combined transport of non-polar and polar substances. In this way, by residing photosensitizer within the membrane, photosensitizing agents are effectively targeted to their place of action but the luminal part inside the liposome particle stays free for the inclusion of other substances, including drugs that may have a beneficial effect on the therapy.

In addition, the combination of monosaccharides as glucose and the photosensitizer attached to phospholipids is an excellent tool to preserve the size of the liposomes during freeze-drying and rehydration using a physiological common carbohydrate instead of disaccharides.

This versatile concept allows the addition of substances, that will have a beneficial effect on the therapy. The combination of two or more substances together with a membrane bound photosensitizer within one vehicle will allow one to directly or indirectly influence the oxygen content of the targeted cells thereby influencing the efficacy of PhotoDynamic therapy. For instance, such effects can be achieved by adding inhibitors of enzyme activities like inhibitors of the mammalian thioredoxin reductase (TrxR). Thus, effective only after reaching the cytoplasm of the targeted cells, the inhibitor will block the Trx/TrxR pathway which normally acts as an antioxidant.

EXAMPLE 1 Preparation of Liposomes containing m-THPC

mTHPC (Temoporfin) was synthesized as described in U.S. Pat. Nos. 4,992,257 and 5,162,519, incorporated herein by reference.

Liposomes were prepared according to the following general procedure:

Non-polar photosensitizer, ascorbic palmitate and the phospholipids are dissolved in chloroform/methanol. The solution is then dried under vacuum using a rotary evaporator until the chloroform/methanol mixture is not detectable by gas chromatography anymore. Water for injection is added to rehydrate the lipid film at a temperature of 50° C. for at least 2 hours. The mixture is then passed through a homogenizer filter system using a final pore size of 100 nanometer. Optionally, the rehydration water is supplemented with monosaccharides or polyalcohols. The filtrate is collected, filled into vials and optionally freeze dried. The freeze dried composition is reconstituted with water for injection prior to administration.

Using the foregoing procedure, several different preparations of the liposomal formulation were prepared as follows:

EXAMPLE 1a

Ingredient Amount % w/v mTHPC  0.05 to 0.15 Dipalmitoyl Phosphatidyl Choline  0.5 to 2.0 Dipalmitoyl Phosphatidyl Glycerol  0.05 to 0.2 pegylated Distearoyl Phosphatidyl  0.05 to 0.2 Ethanolamine Ascorbic Palmitate 0.002 to 0.004 Water for Injection as required to achieve desired concentrations above

EXAMPLE 1b

Ingredient Amount % w/v mTHPC  0.05 to 0.15 Dipalmitoyl Phosphatidyl Choline  0.5 to 2.0 Dipalmitoyl Phosphatidyl Glycerol  0.05 to 0.2 Ascorbic Palmitate 0.002 to 0.004 Water for Injection as required to achieve desired concentrations above

EXAMPLE 1c

Ingredient Amount % w/v mTHPC  0.05 to 0.15 Dipalmitoyl Phosphatidyl Choline  0.5 to 2.0 Dipalmitoyl Phosphatidyl Glycerol  0.05 to 0.2 Glucose  2.0 to 12.0 Ascorbic Palmitate 0.002 to 0.004 Water for Injection as required to achieve desired concentrations above All were found to function well in their use according to the present invention.

EXAMPLE 2 Physical and Chemical Stability of Liposomal m-THPC

The physical stability of the liposomal formulations was measured by monitoring the particle size distribution by photon correlations spectroscopy. Stability of liposomal mTHPC Mean Particle Size Storage Conditions distribution (nm) Initial 166 23° C. - 1 Month 177 23° C. - 4 Month 167

EXAMPLE 3 Localization of mTHPC Within the Liposomal Bilayer of the Formulation

Gel filtration of liposomal formulation performed on Sephadex G50 columns. As shown in FIG. 1, lipids and mTHPC show the same distribution over all fractions indicating a physically interaction of both components i.e. integration of mTHPC into the membrane bilayer. The distribution does not change markedly after destroying the liposomal structure by ultrasonication, as shown in Tables 1 and 2.

EXAMPLE 4 Pharmacokinetic Properties in Mice

Colo 26, a non-metastasizing mouse colorectal tumor cell line, syngeneic to Balb/c mice, was used.

Cells were maintained as a monolayer culture in Roswell Park Memorial Institute (RPMI)-1640 medium completed with 10% heat-inactivated fetal calf serum, 1% streptomycin-penicillin and 200 mM L-glutamine at 37° in 95% air and 5% CO₂. Six-week athymic female mice (Swiss, nu/nu) were inoculated subcutaneously into the right hind foot with 2×10⁶ Colo26 cells. Two weeks later, as the tumor reached a diameter of 5-7 mm, formulations of m-THPC (0.5 mg/kg) were injected intravenous.

Non-invasive LIF measurements have been performed at three distinct sites: tumor with overlaying skin, symmetric normal tissues with overlaying skin on the left hind foot and elevated skin at different times after drug administration. At the selected time points mice were sacrificed and the fluorescence signals from tumor and normal tissues were measured in direct contact.

FIG. 2 displays the accumulation of mTHPC, product A and B in tumor as a function of time post-injection measured in four mice. Non-invasive measurements demonstrated the trend for the better accumulation of mTHPC in the tumor compared to normal tissues with a best ratio (1.3) at 24 h. Invasive measurements performed in the direct contact with the tumor and muscle at 24 h and 48 h post-injection gave the ratios of 2.7 and 3.0 respectively.

Measurements for product A have been done in one mouse at 0.5 h, 4 h, 6 h, 8 h, 12 h, 24 h, 36 h, 48 h, and 72 h post-dose. Product A has shown similar pharmacokinetic behavior like mTHPC. Compared to mTHPC the highest fluorescence intensity in tumor tissue was already reached after 4 hours after injection.

Measurements for Product B have been done in one mouse at 0.5 h, 4 h, 6 h, 8 h, 12 h, 24 h, 36 h, 48 h, and 72 post-dose. The highest fluorescence intensity in tumor was measured 8 hours after i.v. injection. In comparison to mTHPC product B is showing completely different pharmacokinetic properties. The concentration of Product B was increased in tumor much faster (16 h) than mTHPC.

EXAMPLE 5 Antitumor Activity of Liposomal m-THPC

Colo 26, a non-metastasizing mouse colorectal tumor cell line, syngeneic to Balb/c mice, was used.

Cells were maintained as a monolayer culture in Roswell Park Memorial Institute (RPMI)-1640 medium completed with 10% heat-inactivated fetal calf serum, 1% streptomycine-penicillin and 200 mM L-glutamine at 37° in 95% air and 5% CO₂.

Six-week athymic female mice (Swiss, nu/nu) were inoculated subcutaneously into the right hind foot with 2×10⁶ Colo26 cells. Two to three weeks later, as the tumour reached a diameter of 10-13 mm, formulations of m-THPC (0.5 mg/kg) were injected intravenous. Unless otherwise indicated, 3 mice per group per product were used for each post-PDT.

a. Photodynamic Treatment

Drug-light intervals (DLI) of 0.5 h, 4 h, 6 h, 72 h were used for the products as mTHPC, product A (liposomes and m-THPC) and product B (PEG-ylated liposomes and m-THPC). Each animal was anaesthetized by i.m. injection of ketamine (12.5 mg/ml), then photoirradiated at 652 nm with 10 J/Cm² at 100 mW/cm² using a light diode laser.

b. Evaluation of PDT Effect

Morphological Method

To evaluate the tumor tissue necrosis after PDT treatment, Evans Blue dye method was used.

Mice were injected i.p. (0.25 ml) with Evans blue (1%) immediately after PDT treatment. Twenty four hours later the mice were sacrificed with an overdose of halothan, tumors were ablated and cut longitudinally. As exemplified in FIG. 3, the photos of the whole tumors and tumor slices had been taken.

Unstained necrotic areas were considered as tumor damage:

i. Drug-light interval (DLI)=0.5 h, necrosis was not observed irrespective to the products used.

ii. Drug-light interval (DLI)=4 h. Three mice treated with mTHPC-PDT demonstrated partial tumor necrosis. Two mice treated with product A gave partial tumor necrosis, while the tumor of the third mouse remained intact. Three mice treated with product B-PDT demonstrated tumor necrosis: in two mice the distinct tumor necrosis was observed, while in the one mouse the tumor necrosis was partial.

iii. Drug-light interval (DLI)=6 h; Six mice were used for the product A. Distinct necrosis was noticed in the tumors of two mice treated with product A and four others were intact. For the product B, a distinct tumor necrosis was observed in all mice. Two tumors treated with mTHPC-PDT demonstrated distinct necrosis, one tumor was free of necrosis. mTHPC-PDT tumors that displayed necrosis were confirmed by ocular observations.

Having described preferred embodiments of the invention with reference to the accompanying drawings, it is to be understood that the invention is not limited to the precise embodiments, and that various changes and modifications may be effected therein by those skilled in the art without departing from the scope or spirit of the invention as defined in the appended claims. TABLE 1 mTHPC recovery rate after G50 gel filtration. Volume A x Absorp. (μl) Volume Fraction1 0.0000 175 0.0000 Fraction2 0.1285 175 22.4875 Fraction3 0.4367 175 76.4225 Fraction4 0.1111 175 19.4425 Fraction5 0.0251 175 4.3925 Fraction6 0.0058 175 1.0150 Fraction7 0.0050 175 0.8750 Fraction8 0.0015 175 0.2625 Fraction9 0.0000 175 0.0000 Fraction10 0.0000 175 0.0000 Fractions 0.7137 175 124.8975 Total Probe 0.6278 200 125.5600 Recovery 99.4724 rate (%)

TABLE 2 Lipid recovery rate after G50 gel filtration. Volume kcps x kcps (μl) Volume Fraction1 0.30 175 52.50 Fraction2 28.50 175 4987.50 Fraction3 88.10 175 15417.50 Fraction4 24.40 175 4270.00 Fraction5 4.10 175 717.50 Fraction6 2.30 175 402.50 Fraction7 1.20 175 210.00 Fraction8 0.80 175 140.00 Fraction9 0.60 175 105.00 Fraction10 0.80 175 140.00 Fractions 151.10 175 26442.50 Total Probe 121.90 200 24380.00 Recovery 108.46 rate (%) 

1. A pharmaceutical liposomal formulation for photodynamic therapy comprising a liposomal bilayer which consists substantially of phospholipids, and a therapeutically effective amount of a non-polar photosensitizer.
 2. The liposomal formulation according to claim 1, wherein said phospholipids are selected from the group consisting of dipalmitoyl phosphatidyl choline, dipalmitoyl phosphatidyl glycerol, poly (ethylene glycol)-linked phospholipids and combinations of these three materials.
 3. The liposomal formulation according to claim 1 wherein said photosensitizer is a porphyrin macrocycle photosensitizer.
 4. The liposomal formulation according to claim 1 wherein said porphyrin macrocycle photosensitizer is selected from the group consisting of deuteroporphyrin, etioporphyrin, protoporphyrin, hematoporphyrin, pheophorbide and their di- and tetra-hydroporphyrin derivatives.
 5. The liposomal formulation according to claim 1, which has been freeze dried, further comprising one or more monosaccharides or polyalcohols, and wherein the freeze dried formulation, upon addition of a suitable aqueous vehicle, forms liposomes containing a therapeutically effective amount of the non-polar photosensitizer within the liposomal bilayer.
 6. The liposomal formulation according to claim 5 wherein said monosaccharide is selected from the group consisting of glucose and fructose.
 7. The liposomal formulation according to claim 5 wherein said polyalcohol is selected from the group consisting of inositol and mannitol.
 8. The liposomal formulation according to claim 5 wherein the concentration ratio of monosaccharide to phospholipid is between 1:2 and 1:12.
 9. The liposomal formulation according to claim 5 wherein the concentration ratio of polyalcohol to phospholipid is between 1:2 and 1:12.
 10. The liposomal formulation according to claim 5, reconstituted with an aqueous fluid for pharmaceutical administration.
 11. The liposomal formulation according to claim 1 wherein the therapeutically effective concentration of the photosensitizer is from 0.0001 to 0.15 percent w/v.
 12. The liposomal formulation according to claim 5 wherein the therapeutically effective concentration of the photosensitizer is from 0.0001 to 0.15 percent w/v.
 13. The liposomal formulation according to claim 1 further comprising a component selected from the group consisting of butylated hydroxytoluene, ascorbic palmitate, and combinations of these two.
 14. The liposomal formulation according to claim 5 further comprising a component selected from the group consisting of butylated hydroxytoluene, ascorbic palmitate, and combinations of these two.
 15. The liposomal formulation according to claim 1 wherein the formulation further comprises at least one additional pharmaceutically active substance, especially polar, suitable to have some beneficial effect in a preselected therapy.
 16. The liposomal formulation according to claim 5 wherein the formulation further comprises at least one additional pharmaceutically active substance, especially polar, suitable to have some beneficial effect in a preselected therapy. 